Bearing housing incorporating antimicrobial agent

ABSTRACT

A molded polymeric bearing housing is formed of a moldable polymer base material in combination with a glass fiber reinforcing component. A foaming agent is added to the base material to create a fine structural foam within interior regions of the housing. A density gradient is established between regions adjacent to the surfaces of the housing and the internal regions, thereby reducing the need for reinforcing ribs particularly in a base or mounting portion of the housing. An antimicrobial agent may be added to the housing material to inhibit the growth and proliferation of fungi, molds, bacteria, and so forth. Structural features of the housing may be formed subsequent to the molding process, such as by turning operations. Metal inserts may be provided to avoid crushing of regions of the housing, such as by attachment fasteners. The housing forms a mounting base surface in a single plane coextensive with the footprint of the housing. When the housing is placed in service moisture and debris is prevented from collecting below the housing by conformity of the mounting base surface with the machine support surface. The housing may be formed in a variety of styles, including pillow block styles, tapped base pillow block styles, two and four bolt flange styles, take up frame styles, flange bracket styles and so forth.

This application is a divisional of Application Serial No. 08/921,094filed Aug. 29, 1997 U.S. Pat. No. 6,089,758.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to the field of antifrictionbearings and housings for such bearings. More particularly, theinvention relates to a molded polymeric bearing housing includingfeatures advantageous in certain applications, such as in the food andbeverage industries.

2. Description of the Related Art

A wide range of applications exist for antifriction bearings, such asball bearings, roller bearings, needle bearings and the like. In manyindustrial and material handling systems, such bearings perform afundamental function of permitting rotating machine elements to turnwith little resistance and thereby to effectively transmit power andmotion between drive system components. Applications for such bearingsinclude conveyors, mixers, pump drives, and the like, to mention just afew.

In general, bearings of the type commonly used in most industriesinclude an inner race, an outer race, and a plurality of antifrictionbearing elements disposed therebetween. The bearing elements arecaptured by the races and permit the races to rotate freely with respectto one another. The bearing assembly is typically installed in andsupported by a housing. A number of housing types are known and are incommon usage, including pillow block styles, two and four bolt flangedstyles, take-up frame styles, and so forth. In addition to supportingthe bearing inserts, such housings include features that permit them tobe easily attached to machine frames and other support structures at theapplication. Depending upon the housing style, these features typicallyinclude support feet or flanges traversed by apertures for receivingfasteners. Once mounted on the machine frame, a base surface of thebearing housing generally abuts the machine frame and forms a solidfoundation for both the bearing insert and for the machine elements heldin rotation by the bearing insert.

Housings of the type described above are commonly made of a variety ofmaterials depending upon the particular application, the loads to whichthe bearing insert will be subjected and the environmental conditions ofthe application. For example, in most bearing styles, metal housingsprovide sufficient mechanical support and resistance to loads. However,such metal housings are not well-suited to certain applications.Specifically, in certain industries health or environmental constraintsmay make the use of metal bearing housings difficult or impossible. Inthe food and beverage industries, for example, health requirements oftennecessitate frequent washing of processing and material handlingequipment including bearings and their housings. Under such conditions,conventional metal housings may tend to corrode or otherwise degrade inways that would contaminate the working conditions of the machineryand/or the product processed by the machinery. Similarly, in chemicalprocessing industries and certain marine applications the presence ofcorrosive substances may significantly reduce the life of conventionalmetal bearing housings. In response, the industry has began to employalternative materials for bearing housings, including certain plastics.

In general, conventional plastic bearing housings are available in thesame styles as their metal counterparts. Thus, pillow block bearingstyles are available from various manufacturers which differ onlyslightly from designs available in metal. However, due to manufacturingand processing constraints unique to plastic materials certain featuresof conventional plastic bearing housings present drawbacks which makethem unsatisfactory in specific industrial applications. For example,due to the particular geometry of some bearing housing styles, such aspillow block housings, large volumes of the housing may be present inregions of the housing, while relatively thin or small volumes arepresent in other regions. Due to the exigencies of conventionalinjection molding processes, most conventional designs therefore includeribbed structures in the larger volumes regions to provide the requisitestructural integrity, while providing sufficient material flow andcuring in those regions and avoiding drawing during the curing process.In pillow block designs, for example, ribs are commonly provided belowthe bearing support and the lower support flanges. Some or all of theseribs contact the machine frame when the housing is installed, leavingvoids or cavities below the bearing housing between the housing and themachine frame. While the plastic housing itself may perform adequatelyunder frequent and repeated washdowns, such interstices left between thehousing and the machine frame tend to remain wet or moist. Over time,these areas tend to promote the growth of fungi, molds, bacteria andother microorganisms reducing the utility of the housing and requiringadditional downtime for cleaning or even replacement of the housing.

Industry responses to these problems have been less than satisfactory.For example, one response has been to fill the voids or interstices atthe base of the bearing housing prior to placing the housing in service.In one known approach, the entire base of the housing is overmolded withan elastomeric or thermoplastic elastomer filler in an attempt to coverthe voids and cavities. However, this solution provides a product whichis non-uniform in appearance, and which requires additional tooling andmanufacturing processes, adding to the cost of the final product.

There is a need, therefore, for an improved polymeric bearing housingwhich does not suffer from the drawbacks described above. In particular,there is a need for a bearing housing which can be used in applicationswhere environmental or health conditions require superior resistance tocorrosion, while inhibiting the proliferation of microorganisms.

SUMMARY OF THE INVENTION

The invention provides an innovative polymeric bearing housing and amethod for making such a housing designed to respond to these needs. Thehousing may be constructed in a variety of conventional styles,including pillow blocks, tapped base pillow blocks, two and four boltflanged models, take-up frame models, and so forth. All of the modelsare molded from a polymeric material which can be properly formulated toprovide the requisite mechanical integrity, while providing featuresinhibiting growth of microbes. Specifically, in a preferred embodimentan admixture of the polymeric material and an antimicrobial agent isformed prior to molding. The resulting structure thereby inherentlyinhibits the proliferation of microbes on and about the bearing housing.In accordance with another preferred embodiment, a foaming agent isadded to the polymeric material to create a molded structure havingvarying densities throughout. Specifically, regions of higher densityare formed near surfaces of the housing, while structural foam regionscomprise the interior of the housing. Conventional structural ribs in alower portion of the housing are thereby made unnecessary. The housingtherefore includes a substantially planar support base which can bemounted on a machine frame with substantially no interstices between thehousing and the machine frame.

In a preferred embodiment, the base material from which the bearinghousing is made has a light or white color to provide strong contrastwith potentially contaminating substances, such as in food and beverageapplications. Moreover, for such applications the base polymericmaterial and the other components added to the material all preferablycomply with U.S. Food and Drug Administration standards, making thehousing suitable for use on and around food, beverage, pharmaceuticaland similar products.

Thus, in accordance with the first aspect of the invention, a bearinghousing comprises a unitary body made of a moldable polymeric material.The body includes a bearing insert support portion configured to receiveand support the bearing insert. The body also includes a support baseconfigured to receive and cooperate with fasteners to secure the bearinghousing to a substantially planar machine surface. The support base hasa mounting surface extending substantially in a plane. Thus, the housingmay be installed on a planar machine frame with no interstices formedbetween the body and the frame where moisture or other debris or fluidscan collect.

In accordance with another aspect of the invention, a support housing isprovided for a bearing insert of the type including an inner race, anouter race, and an plurality of bearing elements disposed therebetween.A support housing comprises a bearing insert support portion and anattachment portion. The bearing insert support portion is configured toreceive and support the bearing insert. The attachment portion is formedintegral with the bearing insert support portion and includes aplurality of apertures configured to receive fasteners for securing thesupport housing to a machine support surface. The bearing insert supportportion and the attachment portion both comprise an antimicrobial agentor component for inhibiting growth of microorganisms. In a particularlyadvantageous arrangement, the bearing insert support portion and theattachment portion are made of an admixture of a moldable polymericmaterial and the antimicrobial agent.

In accordance with another aspect of the invention, a method is providedfor manufacturing a housing for a bearing insert. The housing comprisesa bearing insert support portion configured to receive and support thebearing insert, and a mounting portion integral with the bearing insertsupport portion and configured for securing the housing to a machineframe. In accordance with the method, an admixture of a moldablepolymeric material and an antimicrobial agent is formed. The admixtureis injected into a mold to integrally form the bearing insert supportportion and the attachment portion. The housing is then allowed topartially or completely cure and is removed from the mold. In apreferred embodiment, temperatures of surfaces of the mold arecontrolled during the molding and curing steps to form a substantiallyclosed skin on the housing.

In another preferred method for manufacturing a bearing housing, anadmixture of a moldable polymeric material and a foaming agent isformed. The admixture is injected into a mold to integrally form thesupport portion and the mounting portion of the bearing housing. Aparameter of the mold is controlled to form boundary regions adjacent tosurfaces of the housing, and internal regions. The boundary regions havea somewhat higher density than the internal regions. The housing is thenat least partially cured and subsequently removed from the mold.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other advantages of the invention will become apparentupon reading the following detailed description and upon reference tothe drawings in which:

FIG. 1 is a perspective view of a pillow block style bearing housing inaccordance with certain aspects of the invention;

FIG. 2 is a sectional view of the bearing housing illustrated in FIG. 1along line 2—2;

FIG. 3 is a sectional view of the housing illustrated in FIG. 1 alongline 3—3;

FIG. 4 is a perspective view of a tapped base pillow block style bearinghousing in accordance with certain aspects of the invention;

FIG. 5 is a sectional view of the bearing housing illustrated in FIG. 4along line 5—5;

FIG. 6 is a sectional view of the bearing housing illustrated in FIG. 4along line 6—6;

FIG. 7 is a perspective view of a further alternative configurationwherein the bearing housing is formed as a four-bolt flangedarrangement;

FIG. 8 is a sectional view of the bearing housing of FIG. 7 along line8—8;

FIG. 9 is a detailed view of a portion of a bearing housing inaccordance with certain aspects of the invention illustrating relativedensities of a structural foam material of which the housing isconstructed in accordance with a preferred embodiment; and

FIG. 10 is a flow chart illustrating exemplary manufacturing processsteps in a preferred method for manufacturing a bearing housing inaccordance with the invention.

DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS

Turning now to the drawings and referring first to FIG. 1, a bearinghousing, designated generally by reference numeral 10, is illustrated assupported on a machine frame 12. In the embodiment illustrated in FIG.1, bearing housing 10 is a flange mounted pillow block style having acentral region 14 flanked by lateral mounting flanges 16 and 18. Acentral aperture 20 is formed in central region 14. An internal bearingsupport surface 22 bounds aperture 20 for supporting a bearing insert 24(illustrated in broken lines in FIG. 1). It should be noted that theparticular embodiment illustrated in FIG. 1 as well as alternativeembodiments discussed below may be configured for supporting varioustypes of bearing inserts of known configuration. In particular, housing10 may be employed for supporting straight roller bearings, taperedroller bearings, ball bearings, needle bearings, sleeve bearings and soforth.

Each lateral mounting flange 16 and 18 includes mounting apertures 26for receiving fasteners 28. Fasteners 28, typically threaded bolts,extend through apertures 26 when bearing housing 10 is installed, andinto threaded bores (see FIG. 3) in machine frame 12. As will beappreciated by those skilled in the art, various securing arrangementsmay be utilized in place of threaded bores and fasteners 28, such as nutand bolt sets, and the like. In the presently preferred embodiment,support sleeves 30 are disposed within each mounting aperture to provideadditional resistance of the mounting flanges to forces exerted byfasteners 28, thereby resisting crushing of the flanges. Sleeves 30 arepreferably performed of metal, such as stainless steel, and securedwithin mounting apertures 26 during molding of housing 10 as discussedin greater detail below.

Central region 14 of housing 10 preferably includes upper facetedsurfaces 32. A lubrication fitting 34 is threaded into one of thefaceted surfaces to provide a lubrication path for bearing insert 24 asdiscussed below. Housing 10 further includes a substantially planar orflat mounting base 36 extending over its entire footprint. Thus,mounting base 36 lies substantially in a single plane beneath bothlateral mounting flanges 16 and 18 and central region 14. This preferredconfiguration of housing 10 is particularly well suited for mounting ona machine frame 12 having a substantially planar support surface 38. Asdiscussed in greater detail below, the use of an integral uniplanarmounting base 36 permits housing 10 to be mounted on planar surface 38with no entrapped voids or volumes therebetween, reducing the potentialfor collecting moisture, debris and other substances beneath housing 10.

As best shown in FIG. 2, in the illustrated embodiment housing 10 has afront side 40 and a rear side 42, front side 40 being configured tofacilitate insertion of a bearing insert into housing 10. Thus, frontside 40 includes an entry chamfer 44 and a pair of lateral recesses 46(see FIG. 3) at the approximate vertical midpoint of bearing supportsurface 22. Bearing support surface 22 comprises a spherical groove;48formed around the entire annulus of central aperture 20. A pair of sealgrooves 50 are provided on either side spherical groove 48. Theforegoing structure permits a bearing insert having a spherical outerring to be positioned and locked into housing 10 in a manner similar tothat employed in conventional bearing housings. Moreover, once thebearing insert is positioned within housing 10, one or more bearingseals of generally known design may be secured in grooves 50 to inhibitthe ingress of moisture and debris into housing 10. In the illustratedembodiment, housing 10 is bilaterally symmetrical permitting a cover(not shown) to be mounted over either front side 40 or rear side 42 asdesired in particular applications.

FIG. 3 shows the foregoing structures in a transverse section of housing10. As illustrated in FIG. 3, central region 14 is formed integrallywith lateral mounting flanges 16 and 18. Moreover, support sleeves 30extend substantially over the entire height of flanges 16 and 18 andterminate in surfaces generally flush with the upper and lowerextremities of apertures 26. Once tightened in place, fasteners 28 thusbear upon sleeves 30 to securely hold housing 10 in its desired positionon machine frame 12. As noted above, once secured in position, planarmounting base 36 of housing 10 conforms to planar surface 38 of machineframe 12, over substantially the entire footprint of flanges 16 and 18and central region 14.

In the preferred embodiment illustrated, central region 14 and flanges16 and 18 are injection molded from a polymeric material. In thepresently preferred embodiment, housing 10 is formed ofpolybutyleneterephthalate (PBT) in combination with a reinforcing glassfiber. PBT is available from numerous commercial sources, such asDSM-Engineering Plastics of Evansville, Ind. under the commercialdesignation Arnite®. The particular resin utilized preferably complieswith U.S. Food and Drug Administration Standards for use in food andbeverage industries, such as those found in 21 C.F.R. 177.1660.Moreover, the resins utilized for housing 10 may include pigmentscomplying standards promulgated in 21 C.F.R. 178.3297. To facilitate theformation of planar mounting base 36 coextensive with the footprint ofhousing 10, the polymeric material of which housing 10 is formedpreferably constitutes a structural foam material formed by endothermicchemical nucleating and foaming agents added to the polymeric materialprior to injection molding. An acceptable foaming agent for the PBTmaterial presently preferred is commercially available from BI Chemical,Specialty Products Division, Winchester, Va. under the commercialdesignation Hydrocerol CF 40. As will be appreciated by those skilled inthe art, such foaming agents may be added to the polymeric materialprior to injection molding to induce direct gassing to form a very finecell foam.

It has been found that the use of a structural foam for housing 10permits the formation of relatively large volumes in certain regions ofhousing 10 in combination with relatively thin structures in otherregions while resisting material drawing. Specifically,. boundaryregions 52 may be formed adjacent to external surfaces 54 of housing 10while internal regions 56 extend therebetween. Such boundary regions areof relatively higher density than internal regions 56. Moreover, thecombination of the polymeric base material with the foaming agent formsa generally closed skin over the entire external surface 54 of housing10. As best illustrated in FIG. 9, a density gradient is thereforedefined between boundary regions 52 lying closely adjacent to externalsurface 54 and internal regions 56 lying within the larger volumes ofhousing 10. In the presently preferred embodiment, density variations ofsome 5 to 10 percent have been found to stabilize between externalsurface 54 and internal regions 56. As will be appreciated by thoseskilled in the art, the particular density gradient locations and thedensity variations extending through the gradients will vary with thelocal geometry of the housing, with larger volume sections having lowerdensity internal regions than thinner or lower volume sections.

In addition to fiber reinforcing components and a foaming agent, in thepresently preferred embodiment, housing 10 includes an antimicrobialagent additive for inhibiting the growth and proliferation of bacteria,fungi, microorganisms and the like. As used herein, the terms“microorganisms” and “antimicrobial agent” are intended to refergenerally to all such plant and microbial forms. As will be appreciatedby those skilled in the art, such antimicrobial agents may be added tothe polymeric material prior to injection molding and remain effectivefollowing the molding process. An acceptable antimicrobial agent iscommercially available from Thompson Research Associates of Toronto,Ontario, Canada under the commercial designation Ultra-Fresh®.

In the presently preferred embodiment, most external surfaces 54 ofhousing 10 are formed during the molding process. Specifically, mountingapertures 26 are formed around support sleeves 30 which are insertedinto the mold cavity prior to injection of the polymeric material.Moreover, a short lubricant channel 58 is preferably formed through anupper portion of the housing by means of a suitable core pin. Lubricantchannel 58 extends from one of faceted surfaces 32 through an upperportion of central region 14 to bearing support surface 22. Toaccommodate lubricant fitting 44, a threaded sleeve 60 is provided inchannel 58. Sleeve 60 is preferably held by the core pin used to formchannel 58 during the molding process, thereby embedding sleeve 60 intohousing 10 during the molding process. As illustrated, sleeve 60includes a grooved outer profile to reduce the risk of pullout onceembedded into housing 10. It should be noted that this preferredstructure facilitates conversion of housing 10 to a permanentlylubricated bearing housing by elimination of the core used to formchannel 58 and to embed sleeve 60. Moreover, the use of faceted upperfaces 32 allows the core to be eliminated while avoiding the creation ofa cosmetic blemish in the previous location of the core.

Internal features of bearing support surface 22 are preferably formed bymachining operations subsequent to removal of housing 10 from its mold.Thus, spherical groove 48 and seal grooves 50 are preferably formed byturning operations. This preferred methodology both reduces toolingcosts for the injection molding process and facilitates specialconfigurations of housing 10 via the subsequent machining operations.

As mentioned above, the innovative features of the present bearinghousing design may be incorporated in various housing styles. FIGS. 4through 6 illustrate a tapped base pillow block housing constructed inaccordance with the features described above. The tapped base pillowblock housing illustrated, designated generally by the reference numeral62, includes an upper central portion 64 from which lateral supports 66extend. Bolt apertures 68 are formed in each lateral support 66, asillustrated in FIG. 5. Tapped sleeves 70, preferably made of stainlesssteel, are provided within each bolt aperture 68 for receiving andinterfacing with threaded fasteners 28. In the illustrated embodiment,sleeves 70 have a grooved profile to resist pullout. Portions of theprofile may be faceted (e.g. hexagonal) to resist twisting within thehousing under the influence of fasteners 28. Each sleeve is preferablyinserted by means of a core provided in the mold used to form housing62. As discussed above with respect to housing 10, housing 62 ispreferably formed of a polymeric material such as PBT and includes aglass fiber reinforcing component. Moreover, in the preferred embodimenta planar mounting base 36 is formed on housing 62 such that housing 62may be mounted directly on a planar mounting surface 38 of a machineframe with no interstice therebetween. To facilitate formation of planarmounting base 36, a foaming agent is added to the polymeric materialused to mold housing 62, creating boundary regions 52 between whichinternal regions 56 of lower density stabilize as discussed above. Inthe embodiment illustrated in FIGS. 4 through 5, features of the moldedhousing are formed via subsequent machining operations, such asspherical bearing support group 48 (see FIG. 6) and seal grooves 50 oneither side of spherical groove 48.

FIGS. 7 and 8 illustrate a four bolt flanged bearing housingincorporating the innovative features described above. Thus, as shown inFIG. 7, a four bolt flanged housing 72 includes a raised central portion74 surrounded by a peripheral flange 76. A central aperture 20 is formedin central portion 74 and a bearing support surface 22 surrounds centralaperture 20 as described above with reference to housings 10 and 62.Raised fastener supports 78 are formed in each corner of flange 76 forreceiving fasteners used to secure housing 72 to a planar machinesupport surface. Support sleeves 80, preferably formed of stainlesssteel, are lodged within each fastener support 78 to interface withfasteners and to prevent crushing of fastener supports 78. Asillustrated in FIG. 8, a lubrication channel 58 is formed in centralportion 74 and a lubrication fitting sleeve 60 is lodged within channel58 for receiving a lubrication fitting as described above. Lubricationchannel 58 communicates with bearing support surface 22, andspecifically with spherical groove 48. As in the previous embodiments,housing 72 is formed of a polymeric base material including a glassfiber reinforcing component. A foaming agent is added to the materialprior to molding to create a structural foam in internal regions asdesignated by reference numeral 56. Also as in the previous embodiments,a planar mounting base 36 is formed which directly contacts a planarmounting surface 38 of a machine frame when housing 72 is placed inservice. It should be noted that due to the annular configuration ofhousing 72, the footprint of planar mounting base 36 is similarlyannular. As in the previous embodiments, certain features of housing 72are preferably formed by subsequent machining operations following themolding process. Specifically, spherical groove 48 and a seal groove 50are formed by turning operations.

As mentioned above, the housings of the present invention are formed bya sequence of operations including a molding process in which a specificpolymeric formulation is created to lend favorable properties to thehousings in their final form. FIG. 10 illustrates exemplary steps in themanufacturing process used to form the housings. Prior to the specificmanufacturing steps enumerated in FIG. 10, a suitable mold is formed inaccordance with generally known techniques. Specifically, it has beenfound that the desired shapes can be created in a two-part mold in whichretractable cores are utilized to form the cavities and aperturesdescribed above. Moreover, as will be appreciated by those skilled inthe art, cooling coils are provided adjacent to mold cavity surfaces inorder to afford temperature control during the curing of the housings.Such temperature control is desirable to create a generally closed skinover the entire exterior surface of the housings and to modulate theformation of density gradients in the structural foam material.

The manufacturing process, designated generally by reference numeral 100in FIG. 10, begins with opening the mold cavity as indicated at step102. Sleeves to be included in the final housing are then inserted intothe mold cavity as indicated at step 104, being held in place bysuitable cores or internal protrusions formed in the cavity. Thespecific sleeves utilized and their locations will vary depending uponthe housing type, but will generally include stainless steel sleeveswithin each fastener aperture and a lubrication fitting sleeve forlubricated bearings. Moreover, in the illustrated embodiments, cores areprovided for forming both the central aperture in the housings as wellas the mounting fastener apertures and the lubricant channel asdescribed above.

The desired admixture of the base polymeric material and other agents isprepared as indicated at steps 106 through 112. If the base polymericmaterial does not already include a glass fiber reinforcing component,this component is added as indicated at step 106. At step 108, a foamingagent is added to the admixture to provide the gassing desired forcreation of the structural foam as described above. As indicated at step110, an antimicrobial agent is then added to the admixture of polymer,glass fiber reinforcing material and foaming agent. Where athermoplastic base material is utilized, such as PBT, the polymeradmixture is preheated as indicated at step 112. It should be noted thatthe foregoing steps may occur in various orders depending upon thespecific materials utilized and their initial and desired forms. Forexample, in specific applications where an antimicrobial agent is not tobe used, such as in certain chemical processing applications, step 110may be eliminated. Similarly, in certain applications calling for theuse of an antimicrobial agent in a non-structural foam product, theaddition of foaming agent may be dispensed with.

At step 114, the admixture is injected into the mold cavity, and at step116 the internal surfaces of the mold cavity are cooled to promote thecreation of a density gradient in the housing, particularly throughlarger volume regions. The housing is then allowed at least partially tocure as indicated at step 118 and, following the cure period, the moldis opened and the housing is removed as indicated at step 120. In thepresent embodiment, the molded body is permitted to partially cure inthe mold and subsequently to air cure following removal from the mold.Where final features of the housing are still in need of definition, asin the preferred embodiment, final machining operations are performed onthe housing blank as shown at step 122. Specifically, internal groovesand similar features may be conveniently formed by such machiningoperations, reducing the need for special cores.

While the invention may be susceptible to various modifications andalternative forms, specific embodiments have been shown by way ofexample in the drawings and have been described in detail herein.However, it should be understood that the invention is not intended tobe limited to the particular forms disclosed. Rather, the invention isto cover all modifications, equivalents, and alternatives falling withinthe spirit and scope of the invention as defined by the followingappended claims.

What is claimed is:
 1. A support housing for a bearing insert, thebearing insert including an inner race, an outer race and a plurality ofbearing elements disposed therebetween, the support housing comprising:a bearing insert support portion configured to receive and support thebearing insert; and an attachment portion integral with the bearinginsert support portion, the attachment portion including a plurality ofapertures configured to receive fasteners for securing the supporthousing to a machine support surface, and a single, substantiallycontinuous uniplanar mounting surface; wherein the bearing insertsupport portion and the attachment portion comprise an admixture of amoldable polymeric material and an antimicrobial agent for inhibitinggrowth of microorganisms, wherein the admixture further includes afiberglass reinforcing component.
 2. The support housing of claim 1,wherein the attachment portion forms a base on which the support housingis mounted when placed in service.
 3. The support housing of claim 1,wherein the moldable polymeric material comprises a structural foam. 4.The support housing of claim 3, wherein the housing forms asubstantially closed skin on outer surfaces thereof and a porousstructure within interior regions bounded by the skin.
 5. A supporthousing for a bearing, the housing comprising: a body made of a moldableplastic material and forming a bearing support surface for receiving abearing insert and a mounting surface for securing the housing to amachine surface, outer surfaces of the housing being exposed and themounting surface being supported on the machine surface when the housingis mounted thereon, the body including an antimicrobial agent, theantimicrobial agent inhibiting growth of microbes on the outer surfacesand on the mounting surface, wherein the body includes boundary regionshaving a first densities adjacent to the outer and mounting surfaces ofthe housing and an internal regions having second densities between theboundary regions, the first densities being greater than the seconddensities.
 6. A support housing for a bearing, the housing comprising: abody made of a moldable plastic material and forming a bearing supportsurface for receiving a bearing insert and a mounting surface forsecuring the housing to a machine surface, outer surfaces of the housingbeing exposed and the mounting surface being supported on the machinesurface when the housing is mounted thereon, the body including anantimicrobial agent, the antimicrobial agent inhibiting growth ofmicrobes on the outer surfaces and on the mounting surface, wherein thebody comprises an admixture of a moldable plastic material and a fibrousreinforcement material.
 7. The support housing of claim 6, wherein thebody includes boundary regions having a first densities adjacent to theouter and mounting surfaces of the housing and an internal regionshaving second densities between the boundary regions, the firstdensities being greater than the second densities.
 8. The supporthousing of claim 6, wherein the body is a unitary structure made of anadmixture of a moldable plastic material and the antimicrobial agent. 9.The support housing of claim 6, wherein the body is a structural foamincluding a substantially closed skin on the outer surfaces and themounting surface and a porous interior region within the skin.
 10. Thesupport housing of claim 6, wherein the mounting surface of the body issubstantially planar and is substantially flush with the machine surfacewhen the support housing is mounted thereon.
 11. The support housing ofclaim 6, including apertures extending through portions of the body andtransverse to the mounting surface, each of the apertures including ametallic reinforcing insert for receiving a fastener for securing thehousing to a machine surface.
 12. The support housing of claim 6,wherein the bearing support surface is formed by an inner periphery ofan aperture extending substantially transverse to the mounting surface.13. A support housing for a bearing insert, the bearing insert includingan inner race, an outer race and a plurality of bearing elementsdisposed therebetween, the support housing comprising: a bearing insertsupport portion configured to receive and support the bearing insert;and an attachment portion integral with the bearing insert supportportion, the attachment portion including a plurality of aperturesconfigured to receive fasteners for securing the support housing to amachine support surface; wherein the bearing insert support portion andthe attachment portion comprise an admixture of a moldable structuralfoam polymeric material and an antimicrobial agent for inhibiting growthof microorganisms, the housing forming a substantially closed skin onouter surfaces thereof and a porous structure within interior regionsbounded by the skin.
 14. The support housing of claim 13, wherein thestructural foam has a varying density from the skin to the interiorregions.
 15. The support housing of claim 13, wherein the attachmentportion forms a base on which the support housing is mounted when placedin service, and wherein the base includes a base mounting surfaceextending substantially in a plane and coextensive with the base. 16.The support housing of claim 13, wherein the admixture further includesa fibrous reinforcing material.
 17. The support housing of claim 16,wherein the fibrous reinforcing material includes a fiberglassreinforcing component.
 18. The support housing of claim 13, wherein themounting portion includes a substantially planar mounting surface forsecuring the housing to a machine surface.
 19. The support housing ofclaim 18, wherein the mounting surface is substantially flush with themachine surface when the support housing is mounted thereon.